Left ventricular-arterial coupling (VAC), defined as the ratio of arterial elastance (Ea) to left ventricular end-systolic elastance (Ees), is a key determinant of cardiovascular performance. This study aims to evaluate whether left VAC can predict stroke volume (SV) response to norepinephrine (NE) in septic shock patients.
Zhou et al BMC Anesthesiology (2021) 21:56 https://doi.org/10.1186/s12871-021-01276-y RESEARCH ARTICLE Open Access Left ventricular-arterial coupling as a predictor of stroke volume response to norepinephrine in septic shock – a prospective cohort study Xiaoyang Zhou1,2, Jianneng Pan1,2, Yang Wang1,2, Hua Wang1,2, Zhaojun Xu1,2* and Weibo Zhuo3* Abstract Background: Left ventricular-arterial coupling (VAC), defined as the ratio of arterial elastance (Ea) to left ventricular end-systolic elastance (Ees), is a key determinant of cardiovascular performance This study aims to evaluate whether left VAC can predict stroke volume (SV) response to norepinephrine (NE) in septic shock patients Methods: This was a prospective cohort study conducted in an intensive care unit of a tertiary teaching hospital in China We recruited septic shock patients who had persistent hypotension despite fluid resuscitation and required NE to maintain mean arterial pressure (MAP) > 65 mmHg Those patients in whom the target MAP was not reached after NE infusion were ineligible Echocardiographic variables were measured before (baseline) and after NE infusion SV responder was defined by a ≥ 15% increase in SV after NE infusion Results: Of 34 septic shock patients included, 19 (56%) were SV responders Before NE infusion, SV responders had a lower Ees (1.13 ± 0.24 mmHg/mL versus 1.50 ± 0.46 mmHg/mL, P = 0.005) and a higher Ea/Ees ratio (1.47 ± 0.40 versus 1.02 ± 0.30, P = 0.001) than non-responders, and Ea in SV responders was comparable to that in non-responders (1.62 ± 0.36 mmHg/mL versus 1.43 ± 0.28 mmHg/mL, P = 0.092) NE significantly increased Ea and Ees in both groups The Ea/ Ees ratio was normalized by NE administration in SV responders but unchanged in non-responders The baseline Ea/Ees ratio was positively correlated with NE-induced SV increases (r = 0.688, P < 0.001) Logistic regression analysis indicated that the baseline Ea/Ees ratio was a predictor of SV increases induced by NE (odd ratio 0.008, 95% confidence interval (CI): 0.000 to 0.293), with an area under the receiver operating characteristic curve of 0.816 (95% CI: 0.646 to 0.927) Conclusions: The left VAC has the ability to predict SV response to NE infusion in septic shock patients Trial registration: Chinese Clinical Trial Registry, ChiCTR1900024031, Registered 23 June 2019 - Retrospectively registered, http://www.chictr.org.cn/edit.aspx?pid=40359&htm=4 Keywords: Septic shock, Stroke volume, Norepinephrine, Cardiovascular, Ventricular-arterial coupling * Correspondence: nbey_icu@163.com; fhzyyicu@yeah.net Department of Intensive Care Medicine, HwaMei Hospital, University of Chinese Academy of Sciences, Ningbo, Zhejiang 315000, China Department of Intensive Care Medicine, Ningbo Fenghua District Hospital of Traditional Chinese Medicine Medical Community, Ningbo, Zhejiang 315500, China Full list of author information is available at the end of the article © The Author(s) 2021 Open Access This article is licensed under a Creative Commons Attribution 4.0 International License, which permits use, sharing, adaptation, distribution and reproduction in any medium or format, as long as you give appropriate credit to the original author(s) and the source, provide a link to the Creative Commons licence, and indicate if changes were made The images or other third party material in this article are included in the article's Creative Commons licence, unless indicated otherwise in a credit line to the material If material is not included in the article's Creative Commons licence and your intended use is not permitted by statutory regulation or exceeds the permitted use, you will need to obtain permission directly from the copyright holder To view a copy of this licence, visit http://creativecommons.org/licenses/by/4.0/ The Creative Commons Public Domain Dedication waiver (http://creativecommons.org/publicdomain/zero/1.0/) applies to the data made available in this article, unless otherwise stated in a credit line to the data Zhou et al BMC Anesthesiology (2021) 21:56 Background Currently, septic shock remains the leading cause of death in the intensive care unit (ICU) with a high mortality of around 38% [1] Fluid administration is a very important treatment for septic shock, but it is always accompanied by an increased risk of fluid overload and seems to be insufficient to restore the arterial pressure due to the depressed vasomotor tone Thus, vasopressor is advocated to be applied early to achieve a minimum acceptable arterial pressure to guarantee organ perfusion [2–4] Norepinephrine (NE) is recommended as the first choice of vasopressor in the management of septic shock [5] As a potent α1-adrenergic agent with β1-adrenergic properties, NE can increase the left ventricular afterload and myocardial oxygen consumption through restoring vasomotor tone and subsequently improving arterial pressure [6, 7] On the other hand, NE can improve cardiac contractility through stimulating β1-adrenergic receptors and improving coronary perfusion by increasing diastolic arterial pressure (DAP) [6], and it can also increase the left ventricular preload by redistributing venous blood from unstressed to stressed blood volume [2, 8, 9] Given the wide spectrum of impacts of NE on cardiovascular performance, the overall cardiovascular effects of NE are difficult to determine It has been well described that the mechanical efficiency of the cardiovascular system depends on the interactions between the heart and the arterial system [10–12], namely left ventricular-arterial coupling (VAC), which is measured by the ratio of arterial elastance (Ea) to left ventricular end-systolic elastance (Ees) In the physiological conditions, the cardiac function is matched well with the arterial system, and this interaction is modulated dynamically to provide an optimal SV and arterial pressure to perfuse the organ and tissue [10] However, this well-matched interaction will be inevitably broken in some pathological cases, such as septic shock [13], finally causing circulatory failure and worse prognosis [13–15] Among interventions for the treatment of circulatory failure, the optimal treatment should be those that improve the work efficacy of the cardiovascular system with the lowest energetic consumption, which refers to high mechanical efficiency Therefore, it is of interest to explore the effect of NE on the interactions between the heart and the arterial system, since NE exhibited complex effects on cardiovascular performance Moreover, a description of the cardiovascular effects of NE will facilitate a better understanding of the pathophysiologic changes of hemodynamics during NE infusion We therefore conducted this study to describe the relationship between the left VAC and the cardiovascular response to NE in septic shock patients We hypothesized that the left VAC can predict SV response to NE in septic shock, given the fact that the left VAC Page of 11 determines the stroke volume (SV), left ventricular ejection fraction (LVEF), and ejection pressure [10, 16], and it possesses independent diagnostic and prognostic value in multiple diseases [17] Materials and methods This was a prospective cohort study conducted between October 2018 and January 2020 in the 20-bed ICU of HwaMei Hospital, University of Chinese Academy of Sciences (Ningbo, China) This study was conducted in compliance with the Declaration of Helsinki and approved by the institutional ethics committee in our hospital (PJ-NBEY -KY-2019-014-01) and adhered to the Strengthening the Reporting of Observational Studies in Epidemiology (STROBE) guidelines Written informed consent was obtained from the patients or their next of kin This study was part of a study program that was registered in the Chinese Clinical Trial Registry (ChiCTR1900024031) Patients Adult patients (age > 18 years) with septic shock, who had persistent hypotension despite fluid resuscitation and required NE to maintain mean arterial pressure (MAP) > 65 mmHg, were considered for enrollment after ICU admission Septic shock was diagnosed according to the criteria of the third international consensus definitions for sepsis and septic shock [18] The exclusion criteria included: 1) Refractory shock patients in whom the target MAP was not reached after NE infusion and needed to infuse other vasopressors or inotropic agents to maintain MAP; 2) Patients with atrial fibrillation; 3) Patients who were receiving vasoactive agents or cardiac function assist device (such as pacemaker) at the time of enrollment; 4) Patients who had poor echogenicity or could not tolerate the transthoracic echocardiography (TTE) examination Study protocol Radial artery catheterization was performed in all patients after their ICU admission to measure the invasive arterial pressure The initial resuscitation practice adhered to the recommendations of the Surviving Sepsis Campaign [5] and its update [4] These practices included fluid resuscitation, appropriate antibiotic therapy, source control, vasoactive medications, and organ support Fluid responsiveness was evaluated using dynamic echocardiographic indices (e.g the respiratory variation in inferior vena cava diameter, the passive leg raisinginduced changes in SV) before NE infusion start Whether start NE infusion was decided by the physician in charge based on the MAP, fluid non-responsiveness, and fluid volume administered in each patient (at least 30 mL/kg of crystalloid fluid within the first h) NE Zhou et al BMC Anesthesiology (2021) 21:56 dose was adjusted to reach the target MAP (more than 65 mmHg) and maintain MAP stabilization MAP stabilization was defined as a variation of MAP < 10% with NE infusion during a period of at least 15 [19] Other vasoactive drugs or inotropic agents were not considered before the end of the study period Additional sedative and analgesic drugs were used to facilitate invasive mechanical ventilation (IMV) in patients treated with IMV Modifications of ventilator setting or dose of sedative and analgesic drugs and fluid challenges were not allowed during the study period Data collection We recorded the demographic information, source of infection, causative pathogen in culture, and concomitant disease for all patients at ICU admission The blood gas, acute physiology and chronic health evaluation (APAC HE) II score, and sequential organ failure assessment (SOFA) score at the time of enrolment were also collected for each patient Central venous pressure (CVP) was measured before and after NE infusion for all subjects The ratio of arterial oxygen partial pressure (PaO2) to fractional inspired oxygen (FiO2), ventilator parameters, type of sedative and analgesic drug, and length of IMV were collected for patients treated with IMV Finally, we recorded and analyzed the dose of NE administered, urine output, the time elapsed from NE infusion start to MAP stabilization, duration of ICU stay, and cumulative fluid volume (before NE infusion, during the study period, and within the first 24 h after septic shock diagnosis) All patients were followed up to hospital discharge Transthoracic echocardiography TTE examination was performed for all patients by an independent ICU physician using a Philips CX50 ultrasound system (Philips Medical System, Suresnes, France) This trained operator had an operating experience in TTE for more than years and was blinded to our study protocol The left lateral decubitus position was preferred to obtain a good cardiac ultrasound image All patients were connected to an electrocardiogram In the apical four-chamber view, left ventricular enddiastolic volume (LVEDV) and left ventricular endsystolic volume (LVESV) were measured using Simpson’s method, then LVEF was calculated Continuous Doppler transaortic flow was obtained from the apical five-chamber view to measure the aortic velocity-time integral (VTI), pre-ejection time (Tpre-e), and total systolic time (Ttot-s) The diameter of the left ventricular outflow tract (LVOT) was measured in the parasternal long-axis view, and the area of LVOT was then calculated Simultaneously, heart rate (HR), systolic arterial pressure (SAP), and DAP, as well as MAP, were also Page of 11 measured at the time of TTE examination Finally, SV was calculated using the formula: SV = VTI × LVOT area, and cardiac output (CO) was calculated as SV × HR Ea was estimated as (0.9 × SAP)/SV [20], and Ees was calculated using the single-beat method proposed by Chen et al [21] According to the previous publications [22, 23], Ea/Ees > 1.36 was considered as left ventriculararterial uncoupling All measurements were performed at two time points: starting NE infusion (before NE infusion, baseline) and immediately after MAP stabilization (after NE infusion), regardless of the respiratory cycle The representative value for each variable was estimated as the average value of three consecutive measurements The NE-induced SV increase was employed to distinguish the SV responder (NE-induced SV increases ≥15%) from non-responder (NE-induced increases < 15%), where the NE-induced SV increase was calculated as (SV after NE infusion – SV before NE infusion)/ SV before NE infusion × 100% Statistical analysis The distribution of continuous variables was tested for normality using the Kolmogorov–Smirnov test Normally distributed variables were expressed as mean ± standard deviation (SD), and variables with skewed distribution were presented as median and interquartile range (IQR) Categorical variables were expressed as frequency and percentages Comparisons between SV responders and non-responders were assessed using the Student t test, Mann-Whitney U test, or Fisher exact test, as appropriate Comparisons between the two time points within a group were assessed using the Student paired t test The log-rank test was used to compare hospital mortality between the two groups Pearson correlation coefficient was calculated to test the relationship between the baseline Ea/Ees ratio and other cardiovascular variables (including HR, SAP, CVP, LVEDV, LVEF, SV, and NE-induced SV increases) and to investigate whether NE-induced changes in Ea depend more on changes in SAP or SV Univariate logistic regression analyses were used to screen the potential predictors of SV increase induced by NE Given the small sample size, multivariate analysis was not performed Receiver operating characteristic (ROC) curve was constructed for the Ea/Ees ratio, SV, SAP, and LVEDV at baseline to discriminate the SV responder from SV non-responder, and the optimal cutoff value was determined by the maximum of Youden index A sample size of 34 subjects was calculated to have a power of at least 90% to prove the hypothesis that the baseline Ea/Ees ratio could predict an increase in SV of ≥15% in response to NE with an area under the ROC curve (AUC) of 0.8, α of 0.05 The coefficient of variation (CV) and least significant change (LSC) were Zhou et al BMC Anesthesiology (2021) 21:56 calculated to assess the intra-observer reproducibility for these directly measured ultrasound variables, including LVEDV, LVESV, VTI, Tpre-e and Ttot-s, in 10 randomly selected patients Two-sided P value < 0.05 was considered as statistical significance Data analyses were performed using the statistical software SPSS 17.0 (IBM, New York, USA) Results A total of 38 septic shock patients were initially consecutively screened for enrollment After excluding ineligible patients, we included 34 subjects, of which 19 were SV responders and 15 were SV non-responders (Fig 1) The demographic characteristics of the included patients are summarized in details in Table The baseline characteristics of responders were comparable to that of non-responders Most of the included patients (71%) received IMV during the study period, and the duration of IMV was similar between groups SV non-responders probably received more fluid during the first 24 h after the onset of septic shock than responders (P = 0.061) However, the cumulative fluid volumes before NE infusion and during the study period were similar between groups The duration of ICU stay and in-hospital mortality did not differ between groups In the whole studied population, the average value of Ea/Ees ratio before NE infusion was 1.27 ± 0.42, and 10 patients (29%) had an uncoupled ventricular-arterial interaction with an Ea/Ees ratio of > 1.36 Intra-observer reproducibility As shown in Table 2, the intra-observer reproducibility for the directly measured ultrasound variables was acceptable Fig Flow chart of this study NE norepinephrine; ICU intensive care unit Page of 11 Cardiovascular response to norepinephrine infusion Before NE infusion, SV responders had a lower VTI, lower LVEF, and higher LVESV than non-responders The HR, SAP, DAP, MAP, CVP, SV, LVEDV, cardiac index, Tpre-e, and Ttot-s in responders were comparable to that in non-responders (all P > 0.05) Although Ea did not differ between groups, Ees in responders was significantly lower than that in non-responders (P = 0.005), thus resulted in a higher Ea/Ees ratio in responders than non-responders (P = 0.001) (Table 3, Fig 2) In both groups, NE significantly increased the SV The NE-induced SV increases in responders were greater than that in non-responders (21.1 ± 5.4% versus 5.8 ± 5.5%, P < 0.001) Both Ea and Ees were increased by NE in both groups, and the increases in Ea were lower in responders (0.17 ± 0.22 mmHg/mL versus 0.39 ± 0.22 mmHg/mL, P = 0.008) However, the NE-induced increases of Ees in responders did not differ from that of non-responders (0.37 ± 0.26 mmHg/mL versus 0.32 ± 0.21 mmHg/mL, P = 0.577), thus Ea/Ees was normalized by NE in responders, while unchanged in non-responders (Table 3) The individual data on the Ea/Ees ratio for each patient is shown in Fig NE also increased the SAP, DAP, and MAP in both groups Besides, the HR was reduced by NE infusion in both groups Accordingly, NE induced a significant increase in the Ttot-s, but the Tpre-e was unchanged Additionally, the administration of NE was associated with an increase in the LVEDV and VTI in both groups, but not the CVP However, NE infusion resulted in a decrease of LVESV in responders, but not in nonresponders Thus, the LVEF and cardiac index were improved by NE in responders, yet not changed in nonresponders (Table 3) Zhou et al BMC Anesthesiology (2021) 21:56 Page of 11 Table Clinical characteristics and demographic data of the study participants SV responders (n = 19) SV non-responders (n = 15) P value 70 ± 12 69 ± 13 73 ± 11 0.368 24 (71%) 14 (74%) 10 (67%) 0.718 22.5 ± 3.1 22.6 ± 3.1 22.5 ± 3.3 0.932 Variables All patients (n = 34) Age (years, mean ± SD) Gender [Male, n (%)] Body mass index (kg/m2, mean ± SD) Body surface area (m , mean ± SD) 1.65 ± 0.16 1.68 ± 0.17 1.62 ± 0.16 0.300 APACHE II score (mean ± SD) 20 ± 21 ± 20 ± 0.644 SOFA score (mean ± SD) 9±3 9±3 8±2 0.554 18 (53%) 11 (58%) (47%) 0.730 Source of infection, n (%) Lung Urinary tract (21%) (16%) (27%) 0.672 Abdomen (21%) (26%) (13%) 0.426 Bloodstream (21%) (16%) (27%) 0.672 Others (12%) (11%) (13%) 1.000 Co-morbidities, n (%) Hypertension 16 (47%) (47%) (47%) 1.000 Diabetes 10 (29%) (37%) (20%) 0.451 Chronic obstructive pulmonary disease (9%) (11%) (7%) 1.000 Coronary heart disease (6%) (11%) (0%) 0.492 Chronic kidney disease (6%) (5%) (7%) 1.000 0.624 Pathogen type in culture, n (%) Gram-negative 15 (44%) (47%) (40%) Gram-positive (3%) (5%) (0%) Mixed (6%) (5%) (7%) Fungus (6%) (0%) (13%) No pathogen 14 (41%) (42%) (40%) Patients receiving IMV, n (%) 24 (71%) 15 (79%) (60%) 0.276 PaO2/FiO2 (mean ± SD) 262 ± 135 248 ± 134 285 ± 142 0.518 PEEP (cm H2O, mean ± SD) 6±1 5±1 6±2 0.479 Tidal volume (mL/kg of predicted body weight, mean ± SD) 7.1 ± 1.3 6.8 ± 1.2 7.6 ± 1.3 0.129 Fentanyl, n (%) 15 (44%) 10 (53%) (33%) 0.314 Midazolam, n (%) 15 (44%) 10 (53%) (33%) 0.314 Propofol, n (%) 18 (53%) 11 (58%) (47%) 0.730 Duration of IMV [days, median (IQR)] (3–12) (3–13) (3–16) 0.719 Serum lactate level (mmol/L, mean ± SD) 3.5 ± 2.7 2.9 ± 1.4 4.2 ± 3.7 0.194 Patients with left ventricular-arterial uncoupling before NE infusion, n (%) 10 (29%) (42%) (13%) 0.128 Time from NE infusion start to MAP stabilization [min, median (IQR)] 95 (39–158) 86 (37–180) 100 (55–135) 0.862 Cumulative fluid volume before NE infusion (mL, mean ± SD) 1638 ± 569 1542 ± 523 1758 ± 620 0.278 Cumulative fluid volume during the study period [mL, median (IQR)] 193 (90–309) 180 (60–350) 210 (120–305) 0.490 Cumulative fluid volume within the first 24 h (mL, mean ± SD) 3744 ± 1251 3389 ± 1181 4194 ± 1228 0.061 NE dose (μg/kg/min, median (IQR)) 0.254 (0.131–0.556) 0.22 (0.09–0.556) 0.44 (0.182–0.556) 0.167 Urine output (mL/kg/h, mean ± SD) 1.32 ± 0.73 1.13 ± 0.41 1.55 ± 0.97 0.133 Duration of ICU stay [days, median (IQR)] (5–16) (6–16) 12 (4–17) 0.958 In-hospital mortality, n (%) (26%) (32%) (20%) 0.485 a P value for comparisons of SV responders and SV non-responders SV stroke volume; APACHE acute physiology and chronic health evaluation; SOFA sequential organ failure assessment; IMV invasive mechanical ventilation; PaO2 arterial oxygen partial pressure; FiO2 fractional inspired oxygen; PEEP positive end-expiratory pressure; NE norepinephrine; MAP mean arterial pressure; ICU intensive care unit; SD standard deviation; IQR interquartile range a Zhou et al BMC Anesthesiology (2021) 21:56 Page of 11 Pearson correlation and logistic regression analysis At baseline, the Ea/Ees ratio was positively correlated with the NE-induced SV increases (r = 0.688, P < 0.001), and was negatively correlated with the LVEF (r = − 0.809, P < 0.001) and SV (r = − 0.560, P = 0.001) The Ea/Ees ratio had no correlations with the HR, SAP, CVP, or LVEDV (all P > 0.05) In addition, the NE-induced changes in Ea seem to be more related to the changes in SAP (r = 0.802, P < 0.01) than that in SV (r = − 0.394, P = 0.021) In the univariate logistic regression analysis, the baseline Ea/Ees ratio was identified as a potential predictor of SV response to NE (P = 0.009) (Table 4) Receiver operating characteristic curve The ROC curves analyses suggested that the baseline Ea/Ees ratio could predict an increase ≥15% in SV after NE infusion, with an AUC of 0.816 (95% CI: 0.646 to 0.927, P < 0.001) (Fig 4) The optimal cutoff value was 1.11, with a sensitivity of 89.5% (95% CI: 66.9 to 98.7%), a specificity of 60.0% (95% CI: 32.3 to 83.7%), a positive likelihood ratio of 2.24 (95% CI: 1.2 to 4.2), and a negative likelihood ratio of 0.18 (95% CI: 0.04 to 0.7) However, the baseline SV, SAP, and LVEDV had no ability to predict the SV response to NE, with an AUC of 0.626 (95% CI: 0.444 to 0.786, P = 0.218), 0.626 (95% CI: 0.444 to 0.786, P = 0.192), and 0.593 (95% CI: 0.412 to 0.758, P = 0.353), respectively Discussion This study was conducted to evaluate the predictive value of left VAC for the SV response to NE in septic shock patients The results suggested that SV responders had an altered baseline left VAC, which was significantly greater than that in SV non-responders, and the baseline left VAC was positively correlated with the NE-induced SV increases This study found that the baseline left VAC had the ability to predict SV response to NE infusion in septic shock patients, and the NE-induced SV increase was due to the normalization of left VAC, which was mainly attributed to the improvement of Ees rather than Ea Additionally, the current study suggested that both VTI and Ees were improved after NE infusion, indicating an improvement in cardiac contractility, which was consistent with the findings in a previous study [24] However, the LVEF was not simultaneously improved in the non- responder group This result is not surprising, because LVEF is not a reliable index of cardiac contractility, and it also depends on the ventricular afterload [23] Several studies [25, 26] had demonstrated that fluid responsiveness was a factor that influenced the effects of various interventions on the left VAC These studies [25, 26] found an increase in SV and a decrease in Ea, resulting in an improved left VAC, after fluid loading in fluid responders Thus, confirmation of fluid non-responsiveness before NE infusion start was an important process in our study Moreover, we did not allow the fluid challenge during the study period Finally, the cumulative volume of fluid infusion during NE infusion was small, and it was similar between responders and non-responders However, we found a significant increase in LVEDV in both groups It could not conclude that NE increased the ventricular preload, because the small changes in LVEDV were probably not clinically relevant Thus, the small fluid volume administered during NE infusion should have, if have to be considered, a very limited impact on our results Given that the changes in Ea and Ees were largely different between SV responders and non-responders, we speculated that the SV responsiveness to NE might be determined by the comprehensive effects of NE on the left VAC In our study, we found that SV nonresponders had a normal left VAC, Ea, and Ees at baseline Administration of NE induced a similar improvement in both Ea and Ees, resulting in an unchanged left VAC, thus the potential increase in SV might be counterbalanced by the NE-induced increase in Ea which means a proportional increase in the end-systolic pressure (ESP) at a given SV On the contrary, SV responders had an abnormal baseline left VAC (Ea/Ees ratio > 1.36) that mainly resulted from impaired Ees After NE administration, the left VAC was normalized, and it was mainly attributed to the improvement of Ees rather than Ea The large improvement in Ees finally caused a significant increase in SV despite the small increase of Ea These findings indicated that NE seemingly exerted a main inotropic effect in patients with abnormal left VAC, and exerted similar inotropic and vasoconstrictive effects in patients with normal left VAC Furthermore, the comprehensive effect of NE on the interaction between cardiac and arterial performance was determined by the baseline left VAC Our study suggested the ability of the baseline left VAC to predict the Table Intra-observer reproducibility for directly measured ultrasound variables Variables LVEDV LVESV VTI Tpre-e Ttot-s CV (%, 95 CI) 3.6 (2.8–4.5) 4.7 (3.7–5.7) 1.9 (1.3–2.5) 6.1 (3.9–8.4) 2.3 (1.7–2.9) LSC (%, 95 CI) 5.8 (4.5–7.2) 7.6 (6.0–9.2) 3.0 (2.1–4.0) 9.8 (6.2–13.4) 3.6 (2.7–4.6) CV coefficient of variation; LSC least significant change; LVEDV left ventricular end-diastolic volume; LDESV left ventricular end-systolic volume; VTI velocity-time integral; Tpre-e pre-ejection time; Ttot-s total systolic time; CI confidence interval Zhou et al BMC Anesthesiology (2021) 21:56 Page of 11 Table Cardiovascular responses to norepinephrine in stroke volume responders and non-responders Variables SV responders (n = 19) Before NE HR (beats/min) 112 ± 19 SV non-responders (n = 15) After NE Before NE 104 ± 20 c d SAP (mmHg) 84 ± 112 ± 14 DAP (mmHg) 48 ± 64 ± d d MAP (mmHg) 60 ± 80 ± CVP (mmHg) 9±4 10 ± VTI (cm) 16.9 ± 3.2 20.3 ± 3.3 SV (mL) 48 ± 10 58 ± 11 106 ± 18 d d d After NE 96 ± 21 109 ± 11 47 ± 56 ± d d P value b 0.384 0.255 0.247 0.456 0.535 0.006 a c 81 ± P value d 59 ± 73 ± 0.269 0.027 8±5 9±3 0.498 0.329 20.3 ± 4.4 21.4 ± 4.1 c 0.012 0.380 53 ± 12 56 ± 11 c 0.219 0.534 c LVEDV (mL) 100 ± 12 104 ± 12 95 ± 13 98 ± 12 0.261 0.145 LVESV (mL) 52 ± 48 ± d 43 ± 10 43 ± 0.004 0.061 47 ± 54 ± d 54 ± 56 ± 0.006 0.255 Cardiac index (L/min/m ) 3.2 ± 0.9 3.6 ± 1.0 d 3.5 ± 0.8 3.3 ± 0.8 0.440 0.276 Tpre-e (ms) 61 ± 17 59 ± 14 53 ± 17 56 ± 14 0.145 0.587 Ttot-s (ms) 227 ± 45 246 ± 44 c 253 ± 40 280 ± 41 e 0.083 0.029 d LVEF (%) c Ea (mmHg/mL) 1.62 ± 0.36 1.79 ± 0.42 1.43 ± 0.28 1.81 ± 0.40 0.092 0.877 Ees (mmHg/mL) 1.13 ± 0.24 1.50 ± 0.39 d 1.50 ± 0.46 1.82 ± 0.56 d 0.005 0.057 1.47 ± 0.40 d 1.02 ± 0.30 1.06 ± 0.34 0.001 0.145 Ea/Ees ratio 1.24 ± 0.32 The data are presented as mean ± standard deviation a P value for comparisons of SV responders and non-responders before NE infusion; b P value for comparisons of SV responders and non-responders after NE infusion; c P < 0.01, d P < 0.001, and e P < 0.05 for comparisons of before and after NE infusion within group SV stroke volume; NE norepinephrine; HR heart rate; SAP systolic arterial pressure; DAP diastolic arterial pressure; MAP mean arterial pressure; CVP central venous pressure; VTI velocity-time integral; LVEDV left ventricular end-diastolic volume; LDESV left ventricular end-systolic volume; LVEF left ventricular ejection fraction; Tpre-e pre-ejection time; Ttot-s total systolic time; Ea effective arterial elastance; Ees left ventricular effective end-systolic elastance Fig Scatter plot of individual cardiovascular variables at baseline The solid line represents mean ± standard deviation, and the dotted line represents the optimal cutoff value Ea effective arterial elastance; Ees left ventricular effective end-systolic elastance; SV stroke volume; SAP systolic arterial pressure; LVEDV left ventricular end-diastolic volume Zhou et al BMC Anesthesiology (2021) 21:56 Page of 11 Fig Individual changes in Ea, Ees, and Ea/Ees ratio after norepinephrine infusion Ea effective arterial elastance; Ees left ventricular effective endsystolic elastance; SV stroke volume; NE norepinephrine SV response to NE infusion, which was consistent with the result from the study by Guinot et al [19] Differently, the study by Guinot et al [19] recruited postcardiac surgery patients who usually have low CO and high peripheral vascular resistance, which is different from the hemodynamic profile of septic shock that generalized vasodilation resulting in high CO with or without myocardial depression Over past decades, Ea has been widely recognized as a measure of ventricular afterload [20, 27] According to the calculation formula, Ea is the change in ESP for a given change in SV, and it reflects all the extracardiac forces opposing to ventricular ejection [27] Of note, a previous study [26] found a poor correlation between fluid-induced changes in Ea and those in ESP (ESP was estimated as 0.9 × SAP), and concluded that Ea should Table Univariate logistic regression analysis for screening potential predictors of stroke volume response to norepinephrine Variables Odd ratio 95% CI for odd ratio Lower Upper HR (beats/min) 0.983 0.945 1.021 P value 0.374 SAP (mmHg) 0.934 0.832 1.048 0.244 DAP (mmHg) 0.956 0.832 1.098 0.522 MAP (mmHg) 0.906 0.763 1.077 0.264 CVP (mmHg) 0.941 0.792 1.117 0.486 LVEDV (mL) 0.966 0.911 1.025 0.257 LVEF (%) 1.154 1.028 1.296 0.015 SV (mL) 1.042 0.976 1.114 0.218 VTI (cm) 1.302 1.032 1.643 0.026 NE dose (μg/kg/min) 1.778 0.469 6.738 0.397 Time from NE infusion start to MAP stabilization (min) 1.000 0.994 1.006 0.940 Ea/Ees ratio 0.008 0.000 0.293 0.009 SV stroke volume; NE norepinephrine; HR heart rate; SAP systolic arterial pressure; DAP diastolic arterial pressure; MAP mean arterial pressure; CVP central venous pressure; VTI velocity-time integral; LVEDV left ventricular end-diastolic volume; LVEF left ventricular ejection fraction; Ea effective arterial elastance; Ees left ventricular effective end-systolic elastance; CI confidence interval Zhou et al BMC Anesthesiology (2021) 21:56 Page of 11 Fig Receiver operating characteristic curves to discriminate stroke volume response to norepinephrine Ea effective arterial elastance; Ees left ventricular effective end-systolic elastance; SV stroke volume; SAP systolic arterial pressure; LVEDV left ventricular end-diastolic volume not be used in isolation as an index of left ventricular afterload Inconsistent with the previous study, the current one indicated that the NE-induced increases in Ea were related well to the NE-induced increases in SAP (r = 0.802, P < 0.01) Different interventions might be a potential explanation for these conflicting findings In their study, fluid loading primarily increased the SV and thus led to a reduction of Ea, despite the increases in SAP Conversely, in our study, NE increased the Ea by improving the SAP through its main vasoconstrictive effect Based on these findings, whether Ea can be considered as an index of ventricular afterload still needs more discussion The current study has a main clinical implication that the evaluation of left VAC before NE infusion is helpful to identify which population will benefit from the use of NE Maintenance of perfusion pressure while still sustaining adequate CO is crucial for hypotensive patients [9] Theoretically, among hypotensive patients treated with NE to restore the arterial pressure, those patients with increased SV after NE infusion may suffer from better clinical prognosis than those with unchanged or decreased SV Our study indicates that septic shock patients with a baseline left VAC > 1.11 are more likely to improve the SV with use of NE For those septic shock patients with a baseline left VAC < 1.11, the abuse of a large dose of NE should be avoided because its great afterload effects on the left ventricle might reduce the SV Accordingly, our study provides a new perspective that dynamic assessment of left VAC during the resuscitation of septic shock may be a promising monitoring strategy to guide titrated adjustment of NE dosage to optimize the cardiac work efficacy and thus improve clinical prognosis There are several limitations to our study Firstly, the small fluid volume administered during the study period might affect the left VAC to a small extent While we had restricted changes in some variables that might affect the left VAC (e.g IMV setting, fluid challenge), the fluid administration was not completely restricted during the study period because it was unrealistic in the clinical practice due to the relatively long study period (median duration of 95 min) Secondly, IMV and sedative and analgesic drugs may also be confounders Zhou et al BMC Anesthesiology (2021) 21:56 affecting the left VAC due to its hemodynamic effects [28–30] Unfortunately, we did not analyze the IMV parameters and the dose of sedatives and analgesics because of the limited sample size Nevertheless, the use of IMV and sedatives or analgesics would not prevent the deduction of the conclusion, because modifications of these variables were not allowed during the study period Lastly, as discussed previously [19, 23, 25], the method used for the estimation of Ea and Ees remains a challenge for the reliability of our findings Estimation of Ees in our study was based on the noninvasive single-beat method [21] that assumed a load-independent linear end-systolic pressure-volume relationship and a constant volume axis intercept (V0) of the relationship curve However, a previous study reported a significant correlation between the V0 and cardiac function [14] Thus, changes in V0 resulted from impaired cardiac contractility might affect the estimation of Ees Furthermore, we measured the radial arterial pressure as a surrogate of aortic systolic pressure to calculate the Ea However, the radial arterial pressure was reported to be less accurate than the femoral arterial pressure to estimate the Ea [26] and it may be imprecise to represent the aortic systolic pressure in septic shock due to the collapsed circulatory system [23] Even so, it would not affect the precision of calculation of Ea/Ees ratio because of the similar influences on the calculation of Ea and Ees Thus, the left VAC can be considered as a valid predictor of SV response to NE Conclusions Administration of NE induced changes in Ea and Ees in patients with septic shock The SV response to NE was determined by the comprehensive effects of norepinephrine on the left VAC, which depended on the left VAC at baseline The baseline left VAC had predictive value for the SV response to NE infusion in patients with septic shock Abbreviations ICU: intensive care unit; NE: norepinephrine; CO: cardiac output; DAP: diastolic arterial pressure; SV: stroke volume; VAC: ventricular-arterial coupling; Ea: effective arterial elastance; Ees: left ventricular effective endsystolic elastance; CVP: central venous pressure; LVEF: left ventricular ejection fraction; MAP: mean arterial pressure; TTE: transthoracic echocardiography; IMV: invasive mechanical ventilation; APACHE: acute physiology and chronic health evaluation; SOFA: sequential organ failure assessment; PaO2: arterial oxygen partial pressure; FiO2: fractional inspired oxygen; LVEDV: left ventricular end-diastolic volume; LVESV: left ventricular end-systolic volume; VTI: aortic velocity-time integral; Tpre-e: pre-ejection time; Ttot-s: total systolic time; LVOT: left ventricular outflow tract; HR: heart rate; SAP: systolic arterial pressure; ESP: end systolic pressure; SD: standard deviation; IQR: interquartile range; ROC: receiver operating characteristic; AUC: area under the ROC curve; CV: coefficient of variation Acknowledgements Not applicable Page 10 of 11 Authors’ contributions XZ designed the study, enrolled patients, analyzed and interpreted data, and drafted the manuscript JP enrolled patients, performed the statistical analysis, and helped to acquire and interpret data YW and HW enrolled patients, acquired data, and helped to perform the statistical analysis ZX and WZ designed the study, analyzed and interpreted data, and revised the manuscript All authors read and approved the final manuscript Funding This study was supported by the grants from Zhejiang Medicine and Health Science and Technology Project (No 2019KY184) and Natural Science Foundation of Zhejiang Province (No LY19H190001) The funders had no role in the design of the study or collection, analysis, or interpretation of data or writing the manuscript Availability of data and materials The datasets used and/or analyzed during the current study are available from the corresponding author on reasonable request Ethics approval and consent to participate This study was approved by the institutional ethics committee in HwaMei Hospital, University of Chinese Academy of Sciences Written informed consent was obtained from the patients or their next of kin Consent for publication Not applicable Competing interests The authors declare that they have no competing interests Author details Department of Intensive Care Medicine, HwaMei Hospital, University of Chinese Academy of Sciences, Ningbo, Zhejiang 315000, China 2Ningbo Institute of Life and Health Industry, University of Chinese Academy of Sciences, Ningbo, Zhejiang 315000, China 3Department of Intensive Care Medicine, Ningbo Fenghua District Hospital of Traditional Chinese Medicine Medical Community, Ningbo, Zhejiang 315500, China Received: 19 September 2020 Accepted: 28 January 2021 References Vincent JL, Jones G, David S, Olariu E, Cadwell KK Frequency and mortality of septic shock in Europe and North America: a systematic review and meta-analysis Crit Care 2019;23(1):196 Hamzaoui O, Shi R Early norepinephrine use in septic shock J Thorac Dis 2020;12(Suppl 1):S72–7 Scheeren TWL, Bakker J, De Backer D, Annane D, Asfar P, Boerma EC, et al Current use of vasopressors in septic shock Ann Intensive Care 2019;9(1):20 Levy MM, Evans LE, Rhodes A The surviving Sepsis campaign bundle: 2018 update Intensive Care Med 2018;44(6):925–8 Rhodes A, Evans LE, Alhazzani W, Levy MM, Antonelli M, Ferrer R, et al Surviving Sepsis campaign: international guidelines for Management of Sepsis and Septic Shock: 2016 Intensive Care Med 2017;43(3):304–77 Hernández G, Teboul JL, Bakker J Norepinephrine in septic shock Intensive Care Med 2019;45(5):687–9 Espinoza EDV, Hernandez G, Bakker J Norepinephrine, more than a vasopressor Ann Transl Med 2019; 7(Suppl 1): S25 Persichini R, Silva S, Teboul JL, Jozwiak M, Chemla D, Richard C, et al Effects of norepinephrine on mean systemic pressure and venous return in human septic shock Crit Care Med 2012;40(12):3146–53 Maas JJ, Pinsky MR, de Wilde RB, de Jonge E, Jansen JR Cardiac output response to norepinephrine in postoperative cardiac surgery patients: interpretation with venous return and cardiac function curves Crit Care Med 2013;41(1):143–50 10 Guarracino F, Baldassarri R, Pinsky MR Ventriculo-arterial decoupling in acutely altered hemodynamic states Crit Care 2013;17(2):213 11 Binkley PF, Van Fossen DB, Nunziala E, Unverferth DV, Leier CV Influence of positive inotropic therapy on pulsatile hydraulic load and ventricularvascular coupling in congestive heart failure J Am Coll Cardiol 1990;15(5):1127–35 Zhou et al BMC Anesthesiology (2021) 21:56 12 Elzinga G, Westerhof N Matching between ventricle and arterial load Circ Res 1991;68(6):1495–500 13 Yan J, Zhou X, Hu B, Gong S, Yu Y, Cai G, et al Prognostic value of left ventricular-arterial coupling in elderly patients with septic shock J Crit Care 2017;42:289–93 14 Ky B, French B, May Khan A, Plappert T, Wang A, Chirinos JA, et al Ventricular-arterial coupling, remodeling, and prognosis in chronic heart failure J Am Coll Cardiol 2013;62(13):1165–72 15 Antonini-Canterin F, Enache R, Popescu BA, Popescu AC, Ginghina C, Leiballi E, et al Prognostic value of ventricular-arterial coupling and B-type natriuretic peptide in patients after myocardial infarction: a five-year followup study J Am Soc Echocardiogr 2009;22(11):1239–45 16 Huang SJ Measuring cardiac output at the bedside Curr Opin Crit Care 2019;25(3):266–72 17 Ikonomidis I, Aboyans V, Blacher J, Brodmann M, Brutsaert DL, Chirinos JA, et al The role of ventricular-arterial coupling in cardiac disease and heart failure: assessment, clinical implications and therapeutic interventions A consensus document of the European Society of Cardiology Working Group on Aorta & Peripheral Vascular Diseases, European Association of Cardiovascular Imaging, and heart failure association Eur J Heart Fail 2019; 21(4):402–24 18 Singer M, Deutschman CS, Seymour CW, Shankar-Hari M, Annane D, Bauer M, et al The third international consensus definitions for Sepsis and septic shock (Sepsis-3) JAMA 2016;315(8):801–10 19 Guinot PG, Longrois D, Kamel S, Lorne E, Dupont H Ventriculo-arterial coupling analysis predicts the hemodynamic response to norepinephrine in hypotensive postoperative patients: a prospective observational study Crit Care Med 2018;46(1):e17–25 20 Kelly RP, Ting CT, Yang TM, Liu CP, Maughan WL, Chang MS, et al Effective arterial elastance as index of arterial vascular load in humans Circulation 1992;86(2):513–21 21 Chen CH, Fetics B, Nevo E, Rochitte CE, Chiou KR, Ding PA, et al Noninvasive singlebeat determination of left ventricular end-systolic elastance in humans J Am Coll Cardiol 2001;38(7):2028–34 22 Chen CH, Nakayama M, Nevo E, Fetics BJ, Maughan WL, Kass DA Coupled systolic-ventricular and vascular stiffening with age: implications for pressure regulation and cardiac reserve in the elderly J Am Coll Cardiol 1998;32(5): 1221–7 23 Guarracino F, Ferro B, Morelli A, Bertini P, Baldassarri R, Pinsky MR Ventriculoarterial decoupling in human septic shock Crit Care 2014;18(2):R80 24 Hamzaoui O, Jozwiak M, Geffriaud T, Sztrymf B, Prat D, Jacobs F, et al Norepinephrine exerts an inotropic effect during the early phase of human septic shock Br J Anaesth 2018;120(3):517–24 25 Huette P, Abou-Arab O, Longrois D, Guinot PG Fluid expansion improve ventriculo-arterial coupling in preload-dependent patients: a prospective observational study BMC Anesthesiol 2020;20(1):171 26 Jozwiak M, Millasseau S, Richard C, Monnet X, Mercado P, Dépret F, et al Validation and critical evaluation of the effective arterial Elastance in critically ill patients Crit Care Med 2019;47(4):e317–24 27 Monge García MI, Santos A Understanding ventriculo-arterial coupling Ann Transl Med 2020;8(12):795 28 Dres M, Teboul JL, Monnet X Weaning the cardiac patient from mechanical ventilation Curr Opin Crit Care 2014;20(5):493–8 29 Deryck YL, Fonck K, DE Baerdemaeker L, Naeije R, Brimioulle S Differential effects of sevoflurane and propofol anesthesia on left ventricular-arterial coupling in dogs Acta Anaesthesiol Scand 2010;54(8):979–86 30 Pittarello D, Bonato R, Marcassa A, Pasini L, Falasco G, Giron GP Ventriculoarterial coupling and mechanical efficiency with remifentanil in patients with coronary artery disease Acta Anaesthesiol Scand 2004;48(1): 61–8 Publisher’s Note Springer Nature remains neutral with regard to jurisdictional claims in published maps and institutional affiliations Page 11 of 11 ... was adjusted to reach the target MAP (more than 65 mmHg) and maintain MAP stabilization MAP stabilization was defined as a variation of MAP < 10% with NE infusion during a period of at least... systolic arterial pressure (SAP), and DAP, as well as MAP, were also Page of 11 measured at the time of TTE examination Finally, SV was calculated using the formula: SV = VTI × LVOT area, and cardiac... of sevoflurane and propofol anesthesia on left ventricular-arterial coupling in dogs Acta Anaesthesiol Scand 2010;54(8):97 9–8 6 30 Pittarello D, Bonato R, Marcassa A, Pasini L, Falasco G, Giron